US2449297A - Automatic fluid pressure balancing system - Google Patents

Description

Sept. 14, 1948. F. w. HOFFER 2,449,297

- AUTOMATIC FLUID PRESSURE BALANCING SYSTEM Filed Ilarch 26, 1941 5 Sheets-Sheet 1 f//y/ ////////M A NVENTOH W FRNK WJ'IOFF R man, m

y ARNEYS Sept 14,1948- F. w. HoFFl-:R 2,449,297l

UTOHTIC FLUID PRESSURE BLANGING SYSTE V 5 Sheets-Sheet 2 Filed latch 26, 1941 INVENTOR FER MX A ITCRNEYS FRANK w .noa= BY W i f f Sept. 14, `1948. F. w. HoFFER AUTOMATIC: FLUID PRESSURE BALANCING SYSTEM 5 Sheets-Sheet 3 Filed latch 26, 1941 Sept. -l4, 1948. F. w. HoFFER AUTOIATIC FLUID PESSURE BALAHCING SYSTBI Filed uaron 2s, 1941 5 Sheets-Sheet 4 INVENTOR BY-W: FRANK wzHol-'FER 5 6M Az'roRNEYs- Sept. 14, 1948. F. w. Hor-'FER 2,449,297

AUTOMATIC FLUID RESSURE BALANCING SYSTEM Filed Maron 26, 1941 5 sheets-sheet 5 INVEN TOR .w 'FRANK w.H FFER 2' 'M' Qi/f BY W/mw ZM PRESSURE pump y M ATTORNEYS Patented Sept 14, 1948 UNITED STATES PATENT OFFICE AUTOMATIC FLUID PRESSURE BALANCING SYSTEM Frank W. Hoffen', Detroit, Mich., assignor, by direct and mesne assignments, to James M.

Degnan, Detroit, Mich., as trustee Application March 26, 1941, Serial No. 385,383

Claims. (Cl. 308-122) confined between portions of another member at opposite sides thereof, the total clearance existing is determined by the dimensions of the parts. Relative movement of the floating member under load toward or away from a portion of the other member reduces the instantaneous clearance at the side toward which the load acts, giving rise to a clearance between the complementary surfaces of said members at the side of said floating member which is referred to herein as instantaneous supporting clearance. Since the floating member is positioned by uid pressure acting at opposite sides which automatically tends to maintain the floating member spaced out of contact with said other member, and since the pressure of the fluid is automatically varied in accordance with the spacing of said oating member, the floating member will yield under load toward contact on one side thereof an amount sufcient to produce compensating changes in fluid pressure. The members are thus held in relative fluid suspension, one member being floatably" mounted in the other, so that in the absence of external loading the free floating member is automatically positioned to maintain constant supporting clearance with the other member, or identical or predetermined percentage of total clearance between cooperating sets of complementary surfaces. the said cooperative sets being at opposite sides of the floating member. Upon application of external load the relative position of the members is altered slightly in a manner to decrease the supporting clearance between saidmembers, or to decrease the instantaneous supporting clearance on one side of the floating member and increase the clearance on the opposite side. These changes in clearances automatically result in changes of fluid pressures exerted between the members in a manner to automatically maintain stable equilibrium between external loading and internal fluid pressures.

While the present invention is capable of numerous and diverse applications, it may be illustrated and described more conveniently in connection with bearings, and accordingly in this application I have chosen the bearings as a specific embodiment of the present invention. It will be understood that this specific disclosure of one application of my invention is not intended to be limiting but is made solely to enable those skilled in the art to practice the invention.

Very briefly described, the present invention involves providing means intermediate a pair of members which are relatively movablein a sense which operates to vary the instantaneous ciearance between at least portions of complementary surfaces of said members for partially confining fluid under pressure. The clearance at one side of the float member will be a predetermined percentage of the total clearance between said members.- A continuous flow of fluid under pressure is supplied to the space between the complementary surfaces. Means are provided which are automatically operated by variations in the spacing for controlling the pressure of partially conned fluid. In some instances the pressure of the partially conned fluid is controlled by variably restricting the outlet ilow of fluid therefrom. In other cases the pressure of a partially confined fluid is controlled by variably restricting both the inlet flow of fluid to the space referred to. and the outlet flow of fluid from the space referred to.

The variations in the restriction or restrictions referred to is accomplished by employing the clearance between the members as variably restricting orices for the flow of fluid, either from, or both from and to the partially confined, presi sure or balancing zones, whereby the restriction afforded by these orifices is variable in accordance with variations in spacing between said members.

Means are provided, herein referred to as isolating means, for limiting the area or areas throughout which the balancing pressure can extend. As applied to bearings, the present invention may be employed in cylindrical bearings, spherical bearings, thrust bearings, slides and the like.

With the foregoing general remarks in mind,

`it is an object of the present invention to `provide means for controlling the spacing of a mem- `ber in its manufactured clearance relative to vide means for spacing a pair of members which comprises means for partially confining a body er bodies of fluid under pressure between said members and for varying the pressure of the lpartially confined fluid in accordance with loads imposed on the members.

It is a further object of the invention to provide a body or bodies of partially confined uid under pressure between complementary surfaces of a pair of relatively movable members and varying 'the pressure of the body or-bodies of fluid by variablyA restricting the outlet flow of fluid from said body or bodies.

It is a further object of the invention to provide a body or bodies of partially confined fluid under pressure between complementary surfaces of a pair of relatively movable members and varying 'the pressure of the body of fluid by variably restricting the inlet flow of fluid to said body or bodies, and simultaneously variably restricting the outlet flow of uid from said body or bodies.

Other objects of the inventionl will be apparent as the description proceeds, and when taken in conjunction with the accompanying drawings. wherein: l

Figure 1 is a diagram illustrating the essential elements of a preferred form of my invention;

Figures 2 to 4 are diagrams illustrating the principles of fluid pressure control involved;

Figure 5 is a side elevation, partly in section, of a cylindrical bearing constructed in accordance withV the present invention;

Figure 6 is a section on the line 6 8, Figure 5;

Figure 7 is an enlarged vertical elevation, partly in section, of one end of the bearing shown in Figure 5;

Figure 8 is a section on the line 8--8, Figure 7;

Figure 9 is a transverse section through a bearing illustrating another embodiment of my invention;

Figure l0 is a section on the line l-l, Figure 9;

Figure 11 is an end elevation of a bearing illustrating a somewhat different embodiment of my invention, with parts broken away;

is diagrammatically illustrated in Figure 1. The balancing system comprises a balancing or pressure area, or zone, indicated at IB. The zone I0 is located between a pair of complementary opposed surfaces and is conveniently formed by forming a shallow recess in one of said surfaces.

The spacing between the two.surfaces permits i restricted outflow of fluid under pressure from the zone I0, as indicated by the arrows II,-and in order to limit the area of pressure application, isolating means I2 are provided. The isolating means I2 may conveniently take the for'm of a groove substantially surrounding the balancing or pressure zone I0, and adapted to provide for a discharge of the,l fluid which lpasses from the zone Il) to 'the groove I2, to atmosphere or to a point of lower pressure.

The fluid between the complementary surfaces 'between area I0 and isolation groove I2 has a film pressure gradi-ent the pressure of which grades from the pressure in area I0 to the pressure in groove I2, which extends the effective A balancing area somewhat beyond that defined by the periphery ofv area I0. This extension is llmited by 'the spacing of isolating grooves abouI the balancing area.

The spacing between the complementary surfaces adjacent the pressure areas III and isolation grooves I2, and also the length of "seals therebetween, provide a restriction against flow of fluid from the areas I0 to the grooves I2.

At the opposite side of the floating, relatively movable member, I provide means for controlling the flow of fluid under pressure to the balancing zone. This means takes the form of one or more feed areas I3, which may conveniently be formed by providing grooves in one or" the opposed surfaces at the opposite side of the floating member from the balancing zone I6. Fluid under pressure is admitted to the grooves I3, as indicated by the arrows I4. Adjacent the feed grooves I3 I provide a reduction area I5, which may conveniently take the form of a shallow groove Figure l2 is a section on the line 2 4?, Figure 11;

Figure 13 is an end elevation of a somewhat different embodiment of my invention, with parts broken away, and partly sectioned on the line I3-I3, Figure 14;

Figure 14 is 'a section on the line III-i3, Figure 13;

Figure 15 is a development of the bearing surface of the bearing shown in Figure 13;

Figure 16 is a section on the line I6--I6, Figure 15;

Figure 17 is a section on the line II-iL Figure 15;

Figure 18 is an end elevation, partly in section, of a somewhat different embodiment of my invention;

Figure 19 is a section on the line I9-I 8 of Figure 18, with parts broken away;

Figure 20 is an end elevation, partly in section, of a somewhat diderent embodiment of my invention; and

Figure 21 is a section on the line 2 I-2I of Figure 20 showing the supporting structure therefor in dotted lines.

Referring first to Figures 1 to 4, I have illustrated some of the principles involved in the present4 invention.

In the case where a member is supported for relative movement between a pair of opposed surfaces, the balancing means takes the form of a plurality of balancing systems, one of which formed in the surface of the same member provided with the grooves I3. The spacing between the surfaces of the members and also the length of "seals between feed and reduction grooves, provide a restriction against the flow ol fluid from the grooves I3 to the reduction groove I5. this flow being indicated by the arrow IS. In accordance with well understood principles, the pressure of the fluid in the reduction zone I E will be reduced from the pressure of the fluid in the feed grooves I3.

In order to prevent the application of elevated iiuid pressure over undesirably large areas, I provide isolating means I'I, which may conveniently take the form of outlet grooves formed in the same surface provided-with the groovesy I3 and I5. Due to the spacing between the surfaces referred to, there will be a continuous flow of fluid from the grooves I3 to the grooves Il, as indicated by the arrows I8. In this figure I have Indicated the spacing between the feed grooves I3 and the isolating grooves I'I as somewhat greater than the spacingbetween the feed grooves I3 and the reduction groove I5.

` ious grooves and zones will be described. In Figure 2 I have indicated at A a supply of fluid under pressure, such as exists within the feed grooves I3. At B I indicate a restriction orifice corresponding to the restriction formed by the spacing, and the length of seal" between the cooperating surfaces intermediate the feed grooves I3 `and the reduction groove I5. At'C I indicate a supply of fluid under a reduced pressure, such as exists within the reduction groove I5 and the pressure or balancing zone III communicating therewith. At D I indicate a restriction orifice in the outlet of fluid from the pressure zone Il, such as is formed by the spacing and length of seal between the cooperating surfaces intermediate the pressure zone III and the isolating groove I2. At E I indicate the outlet means for fluid discharged from the pressure zone I0, which corresponds to the isolating groove I2.

If we assume for example, that the floating member is under no load and is therefore supported equidistant from the two opposed surfaces between which it is located, the restrictions afforded by the orifices B and D will be substan- If now a load is applied to the oating member in a direction to decrease the space betweenthe complementary surfaces adjacent the balancing zone I0, making this the supportingclearance, and to correspondingly increase the spacing between the complementary surfaces adjacent the feed grooves I3 and the reduction groove I3, a`

condition illustrated in Figure 3 will exist. Under these circumstances, the cross-section of orifice D, previously described, is reduced and the crosssection of orifice B is correspondingly increased. Under these circumstances and in accordance with well-known physical laws, the pressure in the balancing zone C will in ease. If the relative motion between the me ers is sufllcient to completely or substantially completely close the orifice D, the pressure in the space C will increase to nearly the supply pressure, which was said to be 5000 pounds per square inch. This increased pressure in the zone C acts in a direction tending to move the floating member toward its unloaded position. and if the load imposed upon the oating member is within the capacity of the device. the floating member will assume a new position in which -a condition of static balance exists, and in which the floating member is supported solely by a body or bodies of uid under pressure Iin the zone or zones III. It will be readily apparent that the amount of displacement of the floating member under a given load will vary inversely in accordance with the pressure supplied in the feed grooves I3.

In Figure 4 I have illustrated the condition which exists if the load were applied to the floating member in the opposite direction, such that the spacing between the complementary surface adjacent the feed grooves I3 and reduction groove I! is reduced, and the spacing between the complcmentary surfaces adjacent the pressure zone I0 and the isolating grooves I2 is increased.

Under these circumstances, the pressure in the zone I0 will be decreased an amount dependent on the variation in spacing. as 'to reduce the spacing between the complementary surfaces adjacent the feed grooves I3 and reduction groove Il to zero or substantially to zero, the pressure in the zone C (zone I0) will become substantially atmospheric, or that of the isolating grooves.

Ordinarily a plurality of systems such as shown in Figure 1 are provided. Forv example, in the case of a cylindrical bearing, preferably at least three such balancing areas will be provided spaced about the circum erence ofthe bearing. The pressure ln each I0. will automatically be controlled in a manner to balance the load imposed on the relatively movable member so as to keep the two members out of mechanical engagement with each other.

In Figures 5 to 8 I have illustrated a cylindrical bearing comprising a sleeve 20 in which is mounted a rotatable member 2I. The rotatable member 2I has a pair of spaced, balancing or bearing portions 22 and 23, separated by a reduced portion 24 providing an intermediate space 25. A tapped connection 23 is provided to which suitable conduit means (not shown) may be connected for supplying a continuous flow of fluid under pressure to the space 25,

The portions 22 and 23 of the member 2I are of a size somewhat smaller in diameter than the bore of the sleeve 20 so that the member 2I is mounted within the sleeve 20 for a slight relative movement in a transverse or radial direction, as well as for rotation and axial relative movement.

, According to this embodiment oi' my invention, y

the pressure zones. the isolating grooves, the reduction grooves, and the feed grooves are formed in the enlarged portions 22 and 23 of the: member 2 I. It may be stated at this time that where the relative movable members are mounted for relative4 rotation, the grooves and pressure or balancing zones referred to are preferably located in the member which is not rotatable. This is not necessarily so however, and in the embodiment now being described these grooves and areas are located in the rotatable member 2l,

Referring particularly to Figures '7 and 8, which show the construction of the enlarged portion 23 on an enlarged scale, I have illustrated a 'pair of feed or supply grooves 21 which are closedl at the ends 23 but which open at their ends 29 'into the space 25. Intermediate a pair of feed grooves is a reduction groove 30, which is closedat both ends As best seen in Figure 8, I have indicated three balancing zones 32 together with their associated grooves and passages. It will be observed that a set of feed grooves and reduction grooves is located intermediate a pair of pressure or balancing zones 32, and that therefore intermediate each feed groove 21 and the adjacent pressure or balancing zone 32, there is located an isolating groove 33 which prevents the pressure available in the feed grooves 2l and/or the reduction groove 3l If the load is such f the balancing zones such as from being communicated to the adjacent balancing zone 32. A

As -well illustrated in Figure 8, if a load is imposed downwardly on the portion 23, the pressures in the balancing zones 32 will be modified so as to bring about a condition of static balance. Fluid under the supply pressure is available in the grooves 21. If the portion 23 is moved downwardly in a manner to increase the clearance between the surfaces of the portion 23 and the member adjacent'the upper set of grooves 21 and 30, the effective restriction between the feed grooves 21 and the reduction groovesv 30 is decreased so that the pressure of the fluid in the passage 3l and in the bottom pressure zone 32 communicating therewith, will increase. At the same time, downward movement of the portion 23 relative to the sleeve 20 will decrease the spacing between the surfaces of the portion 23 and the sleeve 2.0 adiacent the bottom of the portion 23 and intermediate the lowermost pressure or balancing zone 32 .and the isolating groove 33 cooperating therewith. This increases the restriction to the flow of fluid from the balancing zone 32 to atmospheric or reduced pressure through the isolating groove 33. This has the effect of further increasing the pressure in the balancing zone 32. It will be appreciated that this increase of pressure in the balancing zone 32 is in a `direction to resist the downward load imposed on the portion 23, and will bring about a condition of static balance while the member 23 is still out of mechanical contact with the lower portion of the sleeve 2U whether the members are at rest or in relative motion.

At the same time the pressure of the fluid in the two uppermost balancing zones 32, as seen in Figure 8, will be decreased by reason of the increased restriction to flow of fluid from the feed grooves 21 to the reduction grooves 33 cooperating therewith.

From the foregoing it will be seen that the arrangement just described provides means which will automatically effect variations in the pressure of partially conned bodies of fluid under pressure in a manner to resist relative transverse or radial movement between the members, and in a manner to provide a resultant fluid pressure equal and opposite to any external loads imposed.

Referring now to Figures 9 and l0, I have illustrated a somewhat different arrangement which, however, operates on exactly the same principles. According to this embodiment of my invention, I provide a sleeve 4l) in which is' rotatably mounted cylindrical float member 4l. Intermediate the sleeve 40 and member 4l I provide a balancing member 42 which is adapted to support the float member r4I solely by automatically controlled fluid pressures.

According to this embodiment of my invention, this structure may be designed lto be dimensionably interchangeable with conventional roller or ball bearings.

This embodiment of my invention illustrates the preferred arrangement in which the various balancing areas, grooves and passages making up my improved balancing system are provided in a relatively stationary member .to cooperate with a relatively rotatable member.

In this embodiment of my invention I have illustrated five pressure or balancing zones 43, which are shown equally spaced circumferentially around the balancing member 42. Intermediate each pair of balancing zones 43 I provide a pair of feed grooves 44 and a reduction groove 45 In the present embodiment of my invention,

unrestricted communication between a reduction groove 45 and the diametrically opposite, cooperating pressure zone 43 is established by circumferential grooves 41, five of which are provided,

one for each of the pressure zones 43 illustrated.

Communication between a reduction groove 45 -and the cooperating circumferential groove 41 is established by a bored passage 45a, and in like manner communication between the circumferential groove 41 and the pressure zone 43 is established by a bored passage 43a. Another circumferential groove 48 is provided which communicates through a passage 49 to an opening 50 which is adapted to be connected by suitable conduit means to a source of fluid under pressure. The groove 48 communicates with the feed grooves 44 by drilled passages 5|.

' The operation of this embodiment of my invention is substantially identical with that previously described, but for completeness Wil1 be briefly reviewed.

l'If it ls assumed that a load is applied to the floating member 4I in a downward direction as seen in Figure 9, the member 4l will move downwardly in a manner to increase the space between the exterior surfaces of the member 4I and the internal surfaces of the balancing member 42 at the upper side of the floating member, and intermediate the upper set of feed grooves 44 and the reduction groove 45. vThe feed grooves 44 are always completely filled with fluid under the supply pressure, and this increase of space between the surfaces referred to reduces the restriction to iiow of fluid from the feed grooves 44 to 4the reduction groove 45. This reduction in the restriction to flow results in an increase in the pressure of the fluid in the reduction groove 45 and, accordingly, results in a corresponding increase of the pressure of ythe fluid in the passage 45a., associated gro e 41, the passage 43a and the lowermost balanc' area 43 in communication therewith. At the same time, downward movement of the floating member 4l under the load referred to reduces vthe supporting clearance between the external surface of the member 4l and the internal surface of the balancing member 42 at the lower side of the floating member. This decrease in the supporting clearance referred to results in an increase in .the restriction to flow of uid from the balancing zone 43 to the isolating grooves 46 adjacent thereto.

The Vincrease in the restriction to the outlet flow of fluid from the balancing zone 43 acts in a manner to further increase the pressure of the fluid partially confined in said balancing zone which pressure. in turn, exerts an upward balancing force on the member 4I. In like manner the other two balancing 4areas 43, which are in open communication with the lower half of the member 4l, have a corresponding but lesser increase in pressure, tending to balance the load applied. In like manner the pressure of the fluid in the two balancing areas 43, which are in open communication with the upper half of the member 4I, is somewhat reduced, and this reduction of counter-balancing pressure assists .the lower balancing areas in balancing the load applied.

`toa thrust bearing adapted to counterbalance a thrust developed axially of a rotating shaft 60. As shown in this figure, the shaft 60 has a reduced portion 6| on which is seated a balancing or float member 62, retained against axial displacement on the shaft `6i'i by means of a locking member 63. Shaft 60 retains the balancing or boat member 62 in parallelism with the complementary surfaces of plates 66 and 66. The balancing member 62 is rotatable within a cylindrical housing 64 composed of plates" 65 and 66, and an annular member 61 assembled in sealed relation by suitable means such as the rivets 66. The housing 64 is tapped as indicated at 69, which connects with a conduit adapted to supply a continuous ilow of fluid under pressure.

In thefembodiment illustrated, I have indicated the annular recessesdeilning the balancing zones or areas and the cooperating grooves as formed in the rotating balancing member 62, but it will be appreciated that if preferred the balancing areas' ing groove 13, a feed groove 1|, and a reduction groove 12, in order. Isolating groove 13 is in registry with an outlet passage 14. A reduction groove 12, at one side of the balancing member 62, is connected by means of passages 15 with the annular balancing zone at the opposite si'de of th'e balancing member 62.

The inner edge of the annular balancing zone 10, at each side of the balancing member 62, is spaced radially outwardly a short distance beyond the bore 16 of plates 65 and 66. The bore 16 is somewhat larger than the shaft 66 so as to provide substantially unrestricted flow of fluid through the space therebetween from the annular balancing zones 1li.

It will be 'appreciated that the cooperating balancing systems shown in Figures 11 and 12 are intended to counterbalance axial loads only, and are not eiective.l to counterbalance radial loads.

The theory of operation of the construction illustrated in these figures is broadly the same as those previously described, but for completeness it willbe reviewed briefly.

Fluid under pressure is admitted through the tapped opening 69 and completely fills the annular space 11 between annular member 61 and the peripheral edge of the balancing member 62. Fluid is admitted from the space 11 to the feed grooves 1| through passages 18 which are pro` vided in suiiicient number so that the feed grooves in the left-hand plate 66. This reduction in the 1| are at all times completely filled with fluid feed grooves 1| to reduction grooves 12 at opposite sides of the balancing member62 will therefore be equal. The duid under pressure in the reduction grooves 'l2 will flow through the passages 16 to the balancing zonesl at opposite sides oi' the balancing member 62. Since the balancing member 62 is equally spaced between the plates 66 and 66, there will be equal restriction to flow of duid out of the balancing zones and, accordingly, the pressure of the fluid in the balancing zones at opposite sides of the balancing member will be equal. Fluid under pressure in the balancing zones 10 will ilow outwardly therefrom. to the isolating grooves 13, and also outwardly through the space provided between the shaft 60 and the bore 16.

If now a load is imposed upon Ithe'shaft 60, tending to move the same to the right as seen in Figure 12, thebalancing member 62 will move slightly to the right and this yielding or change of position will decrease the supporting clearance between the side surface of themember 62 and the adjacent inner surface of the plate 65. "This will have the eilect of increasing the restriction to flow of fluid from the annular space 11 and from the feed groove 1| to the reduction groove v 12, at the right of balancing member 62, and will accordingly result in a drop in pressure in the annular balancing zone 10 located at the left side of the balancing member 62, as seen in Figure 12. At the sam'e time, movement of the balancing member 62 to the right as seen in this figure, will decrease the restriction to outlet flow of fluid from the left-hand balancing zone 10 to .the isolating groove 13, and to the clearance spacing existing between the shaft 60 and the bore 18 restriction to flow of fluid will result in a further decrease in pressure of the fluid contained in the left-hand balancing zone 10.

At the same time, movement of the balancing member 62 to the right as seen in Figure 12, will decrease the restriction against flow of fluid from the annular space 11, and from the feed .groove 1| to the reduction' groove 12 located at the left side of the balancing member 62. This will result in an increase in the pressure of the fluid supplied through the connecting passage 15 and in the balancing zone located at the right-hand side of the balancing member 62. In like manner, this movement of the balancing member 62 will increase the restriction against flow of fluid out of the right-hand balancing zone 10, both to the isolating groove 13 and to the clearance existing between the locking member 63 and the bore 16 provided in the plate 65. This will have the effect of further building up the pressure in the right-hand balancing zone 10 in a manner to resist the load to the right imposed upon the shaft 60. The increase in pressure of the right-hand balancing zone 10, accompanied by the decrease in pressure in the left-hand balancing zone 16,

will .provide a resultant fluid pressure effective on` the balancing member 62 which will exactly counterbalance the load imposed while maintaining the balancing member 62 out of mechanical contact with .the walls of the housing 64 whether said members arein motion or at rest.

In Figures 13 'to 17, I have illustrated yet another embodiment of my invention. In these figures I fhave illustratedthe invention as applied to a spherical bearing, and the arrangement is such that the pressure of bodies of partially conlned duid will be modified in accordance with loads imposed which movement between the parts.

have indicated at 88 a sleeve having a cylindrical bore in which is adapted to be seated a baiancing member 8|, which has a generally spherical inner surface so as to cooperate with a relatively movable iloat member 82 whose complementary exterior surface is spherical.

4 Balancing member 8| in this embodiment'is made up of two parts 8|a and 8|b. Each of the members 8|a and 8|b is provided with a plurality of shallow recesses defining balancing zones 83. As seen -in Figure 13, each of the members 8|a and 8|b is provided with ilve of the balancing zones 83 so that the assembly provides a total of ten of such balancing zones. Intermediateeach of the balancing zones 83 I provide a reduction groove 84 and a pair of feed grooves 85. Surrounding each of said balancing zones 83 on three sides, and isolating the same from the feed and reduction grooves, I provide isolating'grooves 86.4

Passages indicated at 81 yare provided in the sleeve 88 for connection by suitable means to a supply of iluid under pressure, and the exterior surface of the balancing structure 8| is provided with a groove 88 which extends completely around the assembly. As shown in Figure 14 the groove 88 is conveniently formed bychamfering the inner corners of the members 8|a-and 8|b. A suitable number of the passages indicated 89 are provided which connect the groove 88 with the feed grooves 85 previously described.

Each of the reduction grooves 84 is provided with a bore 98 which communicates with a single one of a plurality of grooves 9| formed in the outer periphery of the structure' 8|. Each of the grooves 9| is also provided with a passage, such as indicated at 92, communicating with a correspending one of the pressure or balancing zones 83. The arrangement is such that a-reduction groove 84 is connected by passage 98, a groove f 8|, and passage 92with the pressure or balancing zone 83 diametrically'opposite thereto. Thus, for example, the reduction groove 84 shown adjacent the lower left-hand corner of Figure 14 connects by passage 88 shown in full lines, the communieating groove 8|, and the passage 92 shown in full linesvadjacent the upper right-hand corner of the figure, with the pressure or balancing zone 83 adjacent the upper right-hand corner of Figure 14.

As seen in the embodiment illustrated in these ilgures, there are ten separate balancing zones. Itis necessary to provide ten of the annular grooves 9| in order to connect each of said balancing zones with its corresponding reduction groove.

In Figure 15 I have shown'a development of vthe balancing member 8| shown in Figure 14, and in this igure I have traced by dot-and-dash lines the passage of uid to and from one of said baiancing areas, and I have applied reference numerals only to such of said passages as form a part of a single balancing system. By a single balancing system [I refer to a single pressure or balancing area or zone and its associated feed,

, reduction and isolating grooves, and connecting passages. Fluid is at all times present under pressure in the external feed groove 88 and passes through the passages 89 to the feed grooves 85. Fluid from the feed grooves 85 passes through the restriction afforded by the contiguous inner surface of the balancing member 8| and the cylindrical surface of the member 82, to the reduction groove 84. The reduction groove 84 communicates through' a passage 80 with groove 9|. Groove 9| extends completely around the external circumference of the balancing structure 8|, andy the uid ilows Iboth ways through the groove 8|I from the passage 88 to a second passage 92 which communicates with the balancing zone 83.

It will thus be seen that fluid from thereduction groove 84 is admitted to the cooperating balancing zone 88 which is diametrically opposite thereto. 'I'he balancing zone 83 is removed from reduction groove 84 by 180 in circumference and is located on the opposite side of the median plane of the assembly. The operation of this embodiment of my inven- 15 tion is the same in principle as that of those previously described. Relative displacement of the inner float member 82 in any direction under an external load results in variation` in pressure in the various balancing zones such as to produce a resultant fluid pressure equal and opposite to the imposed load. Under any imposed load within the capacity of the device, the float member assumes a new position which so modifies the pressure acting thereon as to support the float member in its new position and out of mechanical congo'fture which is nevertheless adapted to conform to principles above outlined. In this case, a sleeve member |88 is provided with a plurality of recesses |8| defining pressure or balancing zones. Intermediate the recesses4 |8| the inner periphery of the sleeve |88 is provided with isolating grooves |82. Each -of the zones |8| has communicating therewith a restriction orifice |83 through which iluid under pressure is admitted, and this fluid under pressure is partially conned in the zone 40 8| by the peripheries of the recesses |8| which,

as indicated in Figure 19, are closed at their ends as indicated by the numeral |84. 'Ihe outer surface of the float mem'ber |85 is slightly less than the inside diameter of sleeve |88, so as to permit a`restricted ilow of uid out of pressure zones |8| and suilicient clearance exists so that the oat member is relatively movable in a radial direction with respect to the sleeve member` |88.

For maximum load carrying capacity per square inch of bearing area, it is desirable to proportion at opposite sides. This permits controlled variation in pressure in the balancing areas from pressure nearly equal to the supply pressure to pressures approaching the external pressure.

With the parts as shown in Figure 18 and with no load imposed upon the float member |85, this member will be uniformly spaced at all sides from the sleeve |88. Fluid under pressure is admitted through orifices |83 and exerts a balancing pressure on the member |85. Fluid escapes from the zones |8| by reason of the clearances existing between the parts and enters the isolating grooves |82, from two sides of zones |8l, and from the other two sides direct. If now a radial load is imposed upon the member |85, as for` example in a downward direction as seen in Figure 18, float member |85 moves down to a new position. In

this new position the flow of fluid from the lowerv most pressure zone |8| is additionally restricted by reason of the diminished supporting clearance existing between the complementary surfaces at they lower side of iloat member |00. -This increase inthe restriction of outlet flow of iiuidresults in an increase in the pressure built up in the pressure zones at the lower parto! iloat memupper part of iloat member |05. The resultant Y pressure developed is suiiicient to produce a state of static balance of the inner member, whether the same is stationary or rotating.

It will be observed that in the embodiment just described the control oi the pressure in the pressure zones is` effected solely by automatic variations in the outlet restrictions relative to properly proportioned inlet restrictions. In the u modiilcations previously described, the variation of the pressure of the iluid in the pressure Y zones -was modiiied by automatically varying restrictions in both the inlet to, and the outlet from, the pressure zones.

In Figures 20'and 21 I have illustrated a somewhat diierent embodiment ci my invention in which balancing systems are arranged to balance axial loads, or radial loads, or both. `In these gures I have indicated at ||0 in Figure 21 a supporting structure in which is received a. housing composed of plates and ||2 and an annular ring H3. These parts are assembled together to form a housing through which passes the shaft ||4 carrying balancing member IIS. Surrounding the balancing member IIB and received within the housing is an annular balancing member IIB.

Annular balancing member ||8 is providedl with a plurality of balancing zones or areas between which are isolating grooves |18. feed grooves Il! and reduction grooves |20. Around the exterior of the annular balancing member IIB are provided a plurality of grooves |2| which are adapted to be closed by the annular member ||3 so as -to form passages for iluid extending about the periphery of annular balancing member IIS.

Balancing member H5, as best seen in Figure 20, has a plurality of balancing zones or areas |22 partly surrounded by isolating grooves |23. Intermediate each balancing zone |22 are a. plu- The groove |33 communicates through another passage |30 to a groove |30 which communicates with all ot the feed `grooves |24 previously reierred to.

The dow oi iluid from the balancing areas l and |22 is through an outlet passage |31 communicating with an annular groove llil in bal--` ancing member lll; and from a passage |30 in plate ||2. the passage |30 being in communication with an annular isolating groove to which all of the isolating grooves |23 previously referred to connect.

Since each of the reduction grooves |20 communicates with a balancing larea |221 directly opposite to the reduction groove. thearrangement provides for balancing-out loads tending to disturb the alignment of the shaft ||4 in its` supporting structure.

The operation of the structure illustrated in Figures 20 and -21 is similar to that described in the previous embodiments and will not be described in detail. t

In the foregoing described embodiments ci my invention the arrangement of balancing areas is symmetrical, but it will be appreciated that in some cases it may be desirable to provide a nonsymmetrical arrangement. Thus for example. where a rotary shaft is to be supported against v-loads applied vertically downward Vthereon and in which there is a fixed preloadlng, due perhaps to the weight oi permanently attached machine elements. it may be desirable to provide relatively larger balancing zones or areas around the lower half of the structure as compared to the size of thebalancing zones or areas located around the upper half of the structure. By an arrangement such as this, -it will be possible if desired" to position the shaft under its constant preloading as closely adjacent to the center of the clearance provided as may bedesired. In other cases it may even be desirable to provide the pressure areas of such relative rality of grooves comprising the feed grooves |24 4 and reduction grooves |25. Due to space re: stricti'ons reduction grooves |25 sarily be short and in order to provide for large capacity flow of iluid I provide a plurality, and in the embodiment illustrated three such reduction grooves for each balancing zone. Balancing member ||5 is provided with passages |26I which interconnect each reduction groove |25 with the balancing zone |22 directly opposite to the reduction groove.

Annular member ||'3 is provided with a passage |30 for admitting fluid under pressure to the balancing systems. A ring |3| is applied to the annular member ||3 in tightly sealed relation and is provided with passage |32 which communicates with an annular groove in member ||3 connecting passages |30.

Passages |30 communicate with a groove |33 extending about the periphery of annular balancing member ||6 and iluid is admitted through passages |34 to the feed grooves ||9 at the inner surface of the annular balancing member IIS.

size and number as to position the float member adjacent the upper side of its clearance before external loading 'is applied.

The bearings of the type disclosed herein can be produced in, units which are dimensionally interchangeable with commercial ball and roller bearings, and they can be produced, in addition. in forms not feasible in bali or roller bearings. Some examples are:

1. Spherical bearings or units for 'universal movement, with load capacity for all angles.

2. Cylindrical bearings or units for radial loads and combined rotary and axial movement.

3. Flat bearings for thrust loads in both directions and combined rotary and universal move-` ment in a plane.

4. Units designed for application to reciprc eating machine elements such as machine tables. slides, splines. etc.

5. Nut type bearing units for large threads of any form.

6. Coupling unitslior'limited universal movement. but arranged for positive angular drive.

7. Bearing units in any of the above types which are split or arrangedin sections for assembly purposes.

Since the relative movable members, where my novel system is employed, never touch each other, wear can take place only if one or more of the following conditions obtain:

1. Liquid or gas fed to bearings which will chemically attack material used in bearing members.

"2. Pressure of fluid supplied to bearing fails or becomes subnormal resulting in direct contact ofthe bearing faces while bearing is in opera-- 1 Since all of these possibilities of Wear can be completely avoided by simple time tested means. the result can be practically unlimited bearing life under maximum rated load and speed.

Attention is particularly directed to the fact that the oating bearing member is supported and located by bodies of vfluid (either liquid or gas) and not by films of only microscopic thickness. v In bearings of the type employed prior to my invention, the bearing itself is required to perform the functions of both a bearing and a hydraulic pump in order to build up in part the hydraulic pressure required. Since this type of pumping means is perhaps the most inefficient method of pumping fluids to high pressures, an excessive amount of work is converted into heat to the detriment of both the bearing and pumping functions.v Bearings of the type referred to will only function on certain viscous liquids known as lubricating oils, and even on these specially developed liquids the film thickness dwindles to approximately four millionths (.000004) of an inch in thickness to develop -a unit film pressure of approximately 2000 pounds per square inch; with bearing members running so close, surface finish and contour would need to be practically perfect to prevent irregularities of over .000004 of an inch from dragging against its mating surface, thus creating additional heat. In bearings of the type disclosed herein the depth of the fluid bodies supporting the load is not'limited to even tenths of an inch. The complementary tted surfaces (which are designed to function primarily as automatically variable valving orifices or restrictions) are always separated by a predetermined distance in the order of a few ten-thousandths of an inch up to a few thousandths of an inch. Thus surface irregularities, contour irregularities, and deflection of bearing members under load can be many times greater the required minimum pressure, any liquid or gas which does not chemically attack the bearing materials chosen, may be used. The maximum load carrying capacity of my improved bearing ishot altered by the kind of fluid used if the same uid pressure is used in'all cases.

The load carried by my improved bearings is determined by the iiuid pressure supplied and by the effective areas subjected to the balancing pressure. The maximum unit -load employed in the best plain bearings is in the order of 2000 pounds per square inch, but no such limits exist in the case of my improved bearings.

My improved bearings have zero shake" or backlash. It is noted, however, that the floating member will yield under load a maximum of approximately 90% of the radial clearance under full rated load. It will be appreciated that the degree of yield under a given load is inversely proportional to the fluid pressure employed in a given bearing.

In designing a bearing for a particular appli- -cation the balancing 'areas or vzones and the various grooves referred to are usually located in that member which supports the load more nearly continuously on the same portion of its bearing surface. In this manner each individual balancing area functions more nearly continuously at the same iiuid pressure. Thus cyclic changes from maximum to minimum pressure are avoided with the following advantages:

1. If liquid is fed to the bearing a slight reduction in flow through the bearing will result.

2. If gas isfed to the bearing a considerable reduction in flow to the bearing will result.

3. The clearances on opposite sides of the floating member will not vary under constant load conditions at any point in the cycle.

4. The fiow of fluid through the bearing will not increase with increase in bearing speed.

My improved bearing may be operated at any speeds, however great, at which the centrifugal force will not distort or rupture the rotating member. They are free of vibration and therefore silent at all speeds and loads. Since the complementary bearing surfaces bear only on a body of fluid and never against each other while in operation, the materials may be selected for without causing portions ofthe bearing surfaces to drag and generate heat.

Furthermore, the continuousv ow or oozing of fluid through my improved bearing is so nearly equal at all points that all portions of all bearing surfaces run at the temperature of the fluid, which may be kept as low as desired.

With my improved type of bearing, regardless of whether or not the bearing is in motion or loaded, the bearing members are positively separated by bodies of fluid under pressures, the supply of which is externally generated by eilicient pumping means. Thus there can be no starting drag or wear which in plain bearings occurs at speeds too low to maintain suiiicient oil film pressure.

Since my improved bearings are not lubricated by a liquid film of microscopic (or in some cases zero) thickness, but deep bodies of fluid continuously maintained and supplied at or above structural and processing considerations primarily. My improved bearings require neither a runin nor a warm-up period before the application of rated load at rated speed.

In practicing the invention it is recommended l as a precautionary measure that some means be employed to protect the bearings against insuflicient uid pressure at all times. Conventional or special automatic pressure responsive startand-stop means might well be employed forthis purpose, such, for example, as the means shown in Patent No. 2,160,778 issued May 30, 1939. When, such means is present the bearings will thus lbe in uid suspension before they start working.

My improved bearings will have many diverse fields lof application and I call attention to a number of typical applications:`

l. All important bearing, including pistons, of

internal combustion and steam engines.

2. All important bearings of all types of turbines.

3. Marine propeller shaft bearings.

4. Machine work table or bed ways.

5. Work spindles of milling machines, drill presses, lathes, boring spindles, grinding spindles. grinders, automatics and numerous other types.

6. Electric motor and generator bearings.

7. All important bearings of air compressors and motors including pistons.

8. All important bearings of hydraulic pumps and motors.

9. For positively balancing ilat, cylindrical and other` types of valves in hydraulic equipment of all types.

10. Gyroscope bearings.

11. To replace knife edges in large scales and weighing devices of many types.

12. To replace delicate pivots and knife edges in instruments of many types.

13. Large couplings, universal Joints. slip splines, threads of screw jacks, etc.

14. For rolls required in steel rolling mills.

15. Deep well drilling equipment.

16. Centrifugal pumps of all types.

17. Dredge cutter shaft bearings and dredge pump bearings.

18. Any machines in which oil can not or should not be used.

Due to the absence of rolling contact and vibration there is practically zero tendency for members to creep. In my improved bearings vibration cannot originate on the bearing surfaces, and any vibration set up elsewhere in the mechanism will be damped-out, at least in part, by the dash pot action of the fluid bodies on which the floating member is supported. Impact loads are likewise softened.

Dependable ratings may readily be computed for my improved bearings much more accurately than for previously known types. With the balancing areas and fluid pressures known, simple -arithmetic only is required to determine the maximum safe Working load. Bearing life need not be considered in the rating.

When the grooves and balancing areas are 1ocated in the fixed member, a pressure gauge can be connected through ducts to each balancing area. Under no load condition the reading of all gauges will be identical but when loaded the balancing areas opposing the load will show an increase in pressure, and those opposite will show a corresponding decrease in pressure. The difference in pressure of any opposite pair of balancing areas will show the pounds bearing load at the angle of the reference balancing area.

Due to the fact that there is a continuous ow of fluid through the bearing it is practically impossible for dirt and foreign particles to ilnd direct entrance into my improved bearings. The oil supplied under pressure will of course be filtered to prevent the introduction of dirt and foreign particles at that point.

It will be noted that if a iiuid pressure considerably in excess of the minimum required is employed, there will be no effect except to space the floating member more nearly in the position at which the clearance at opposite sides is identical. However, since more fluid will ooze through the bearing with increased pressure, and since work must necessarily be done in pumping fluid under pressure, a slight decrease in overall eiliciency will result from the use of excess pressure.

In some cases somewhat closer tolerances with respect to clearance control is required as compared to plain bearings. The tolerances on surface finish, however, need not be as close. In comparison with ball or roller bearings the tolerances are fewer in number and not nearly as close.

It is desired to particularly emphasize the fact that while my improved bearing calls for a slight displacement of the floating member in order to 18 effect changes in balancing pressure, the bearing is nevertheless well adapted for precision machines. In precision machines the loads are relatively light compared to the size of the bearings employed and if in addition, relatively high fluid pressures are employed together with slightly less than normal bearing clearance, the bearings can re centered in their clearances as rigidly as desired. Furthermore, with my improved bearing Y there is no friction or temperature problem, no speed problem, no vibration problem, no deterioration problem, no warm up period, no condensation problem, no abrasive dirtproblem, and no deflection or bearing alignment problem.

The depth, size, and contour of the feed grooves, reduction grooves, isolating grooves and balancing areas are not at all critical. Small variations simply impose small hydraulic loads which are automatically balanced out by small variations in fluid pressure of the various balancing areas, exactly as in the case of applied external load. j

In proportioning a bearing ofthe type disclosed herein for a particular application in which the load is known, the uid pressure is determined by the area available for balancing.` Thus if the balancingarea can be doubled, the pressure can be halved. The clearance between thebearing members is dependent largely on bearing size and the amount of deformation from loading, temperature variations etc. In general, the larger the diameter the greater the clearance, but there are many exceptions to this. The minimum safe clearance is usually used in order to keep the uid pump capacity as low as possible. The viscosity of the fluid used is dependent largely on the clearance. There are many exceptions in the case of water bearings of many sizes, and air andsteam bearings of many sizes, etc.

The length of seals" between the feed grooves and the reduction grooves, and between the pressure areas and the isolating grooves is dependent largely on the bearing size. For large size bearings in which the clearance is necessarily relatively large, the length of "seals between these areas 'are increased an amount necessary to offset the effect of increased clearance on fluid flow through the bearing. All bearing factors,` including fluid flow can be exactly predetermined in the light of current knowledge of the leakage of various fluids through various clearances at various pressures and temperatures.

While I have illustrated and described a number of specially diierent modifications illustrating applications of my improved automatic fluid pressure balancing system, it will be appreciated that this specific disclosure is not intended to be limiting but is made merely to enable those skilled in the art to practice my invention, whether in applications similar to those Villustrated or in applications widely differing therefrom but employing the same basic principles, and the scope of my invention is indicated by the appended claims.

What I claim as my invention is:

l. A `device comprising relatively rotatable inner and outer members spaced from and bodily radially movable relative to each other, said members having their opposed surfaces cooperating to form a plurality of circumferentially spaced areas and other areas intermediate and of smaller size than said first mentioned areas, said first and second mentioned areas being arranged in pairs with each pair comprising anarea of larger size and an associated area of smaller size on opposides of said inner member, one of said members` having means for conducting'uid under pressure to each of the areas of smaller size, one of said members having additional means independent of said first mentioned means for conducting fluid from each of the areas of smaller size to the associated areas of larger size, and one of said members having outlet means for conducting fluid from each of the areas of larger size, said opposed surfaces of said members variably controlling the flow of fluid to the areas of smaller size and from the areas of larger size in accordance with relative bodily radial movement of said members.

2. A device comprising relatively bodily movable inner and outer members having pairs of spaced surface portions at opposite sides of said inner member provided with iluid outlet means deiining different sized pressure areas at the opposite sides of said inner member and also provided with recesses forming parts of the areas and spaced from said outlet means, one of said members being provided with inlet means for conducting fluid under pressure to the smaller area, said inlet means opening into the smaller area between and spaced from the recess and the outlet means of the smaller area, one of said members being provided with additional means independent of said outlet and inlet means for 'conducting fluid from the recess of the smaller area to the recess of the larger area, said members being'relatively bodily movable in a direction to simultaneously increase and decrease the spacing between the surface portions at the opposite sides to regulate the fluid pressure in the areas.

3. A device comprising relatively rotatable inner and outer members having spaced surfaces and bodily movable relative to each other, one of said members being provided with fluid outlet ducting fluid from the recess of each of the smaller means defining circumferentially spaced alternate-pressure areas of larger and smaller size, one of said members being provided with a recess forming a part of each area and spaced from said outlet means, said larger and smaller areas being arranged in pairs with each pair comprising a larger area and a smaller area at opposite sides of said inner member, one of said members being provided with inlet means for conducting uid under pressure to each of said smaller areas, said inlet means opening into each of said smaller areas between and spaced from the recess and the outlet means of each smaller area, one of said members being provided with additional means independent of said outlet and inlet means for conducting fluid from the recess of each of said smaller areas to the recess of each ofthe associated larger areas, the relative bodily movement of said members controlling the spacing of the surfaces of said members to regulate the uid pressure in said larger and smaller areas.

4. A device comprising inner and outer members bodily movable relative to each other, said members having opposed surface portions forming a plurality of different sized pressure areas on each of the opposite sides of said inner member. said areas being arranged in pairs with each pair comprising an area of larger size and an associated area of smaller size on the opposite sides of said inner member, one of said members being provided with a recess forming a part of each area, one of said members beng provided with inlet means for conducting fluid under pressure to each of said smaller areas, said inlet means opening into each of said smaller areas at a distance from the recesses of the smaller areas, one of said members being provided with additional means independent of said inlet means for conarea to the recess of each of the associated larger areas and one of said membershaving outlet means for conducting uid from each of said larger areas, said outlet means being located between the smaller and larger areas and spaced from the recesses thereof on each of the opposite sides of said inner member. said opposed surface portions of said members variably controlling the flow of uid to said smaller areas and from said larger areas in accordance with relative bodily movement of said members to cause variation in the spacing between said opposed surface portion.

5. A device comprising relatively rotatable inner and outer members having spaced surfaces and bodily radially movable relative to each other, said outer member being provided with fluid outlet means defining circumferentially spaced alternate pressure areas of larger and smaller size, said outer member being provided with a recess forming a part of each area and spaced from said outlet means, said larger and smaller areas being arranged in pairs with each pair comprisinga larger area and a smaller area at opposite sides of said inner member, said outer member being provided with inlet means for conducting fluid under pressure to each of said smaller areas, said inlet means opening into each of said smaller areas between and spaced from the recess and the outlet means of each smaller area, said outer member also being provided with additional means independent of said outlet and inlet means for conducting fluid from thev recess of each of said smaller areas to the recess of each of the associated larger areas, the relative bodily radial movement of said members controlling the spacing of the surfaces of said members to regulate the iluid pressure in said larger and smaller areas.

6. A device comprising relatively movable inner and outer members having generallyy spherical opposed surfaces cooperating `to form axially spaced sets of circumferentially spaced areas and other areas intermediate and of smaller size than said first mentioned areas, saidareas being arranged in pairs with each pair comprising a larger area of one set and an associated smaller area of the other set located on opposite sides of said inner member, said outer member having means for conducting fluid under pressure to each of said smaller areas. said outer member also having additional means independent of and spaced from said first mentioned means for conducting fluid from each of said smaller areas to the associated larger areas, said outer member further having outlet means independent of and spaced from said first and second mentioned conducting means for conducting-fluid from each of said larger areas. said opposed generally spherical surfaces of said members variably controlling the ilow of fluid to said smaller areas and from said larger areas in accordance with relative bodily movement of said members. y

7. A device comprising an outer member having a bore of generally circular cross section, an

inner member in said bore of slightly smaller generally circular cross section, said members being relatively movable laterally with respect to each other, the inner surface of said outer member and Y the outer surface of said inner member cooperating to control the flow and pressure of fluid flowing between said surfaces from a source of pressure to exhaust, one of said surfaces being substantially smooth and uninterrupted, the other of said surfaces shaped to provide in cooperation 21 with said smooth surface a plurality of fluid pressure balancing systems,each` of said systems comprising a relatively large balancing recess formed in said other surface, a relatively small reduction recess formed in said other surface substantially diametrically opposite to said first recess, a relatively small supply recess closely spaced from said reduction recess, a fluid passage of constant cross section interconnecting said reduction and balancing recess, and means for introducing fluid under pressure to said supply recess, the spacing between said surfaces serving to variabiy restrict flow of fluid from said supply recess to said reduction recess, and from said balancing recess to exhaust, and an isolating groove in said other surface open to exhaust and partially surrounding said balancing recess to limit the area over which fluid pressure in said recess is effective.

8. A device comprising a member having a cylindrical bore, an inner member having a cylindrical surface received in said bore and relatively movable laterally therein to vary the spacing between said surfaces, one of said surfaces being smooth, the other of said surfaces being interrupted to form circumferentially spaced, alternate, relativelylarge and relatively small variable pressure areas, the interruptions in said other surface comprising fluid outlet grooves open to exhaust and forming the boundary between adjacent pressure areas, balancing recesses formed in the relatively large pressure areas, spaced feed and reduction recesses formed in said relatively small pressure areas, said feed recesses being open to a source of uid under pressure, and passages of constant capacity interconnecting each of said reduction recesses with a balancing recess diametrically opposite thereto.

9. A device comprising an outer member having a generally cylindrical bore. an inner generally cylindrical member in said bore, the innerV and outer surfaces of said members being of a size to permit slight relative lateral movement of said members, one of said members having sequentially formed in its generally cylindrical surface in repeating circumferentially spaced relation, an outlet groove. a feed groove and adjacent reduction recess, an outlet groove, and a balan-cing recess, and a passage connecting each of said reduction recesses with a balancing recess substantially diametrically opposite thereto.

10. Bearing structure for a rotary part comprising a member having an opening for receiving said part therein, the inner surface of said opening having a4` plurality of spaced balancing recesses therein, outlet grooves at least partly surrounding said recesses, relatively small reduction recesses intermediate said balancing recesses, inlet means opening into the said surface adjacent said reduction recesses, and passages extending circumferentially around said member and connecting each of said balancing recesses with a diametrically opposite reduction recess.

11. Bearing structure for a rotary part comprising a member having an opening for receiving said part therein, the inner surface of said opening having a plurality of spaced balancing recesses therein, outlet grooves at least partly surrounding said recesses, relatively small reduction recesses intermediate said balancing recesses, a pair of inlet recesses adjacent to but spaced circumferentially from each of said reduction recesses, and passages extending circumferentially around said member and connecting each of said balancing recesses with a diametrically opposite reduction recess.

One Surface, passages intel'cnnecting each 0f said reduction recesses with a diametrlcally opposite balancing recess, and grooves in said one surface intermediate each balancing recess and the adjacent inlets and reduction recesses providing outlets from said balancing recesses which are variably restricted in accordance with the spacing between said surfaces.

13. A device for supporting a rotary shaft having a smooth cylindrical outer surface comprising a body provided with a cylindrical bore, an annular bearing element insertable in said bore and adapted to receive and form a bearing for a rotary shaft, said bearing element having a bore defining an inner cylindrical surface, fluid supply control means comprising fluid inlets opening into the inner surface of said bearing element, reduction recesses adjacent to said inlets to receive a flow of fluid therefrom variably restricted in accordance with the spacing between the surface of said bearing elementI and the adjacent surface of the shaft supported thereby, relatively large balancing recesses formed in the inner surface of said bearing element, passages interconnecting each of said reduction recesses with a. diametricaliy opposite balancing recess, and grooves in the inner surface of said bearing element intermediate each balancing recess and the adjacent inlets and reduction recesses providing outlets from said balancing recesses which are variably restricted in accordance with the spacing between the inner surface of said bearing element and the adjacent surface of the shaft carried thereby.

14. A device for supporting a rotaryl shaft having a smooth cylindrical outer surface comprising a body provided with a cylindrical bore, an annular bearing element insertable in said bore and adapted to receive and form a bearing for a rotary shaft, said bearing element being dimensionaliy interchangeable with ball or roller type bearing assemblies, said bearing element having a bore defining an inner cylindrical surface, fluid supply control means comprising fluid inlets opening into the inner surface of said bearing element, reduction recesses adjacent to said inlets to receive a now of iiuid therefrom variably restricted in accordance with the spacing between the surface of said bearing element and the adjacent surface of the shaft supported thereby, relatively large balancing recesses formed in the inner surface of said bearing element, passages interconnecting each of said reduction recesses with a diametrically opposite balancing recess, and grooves in the inner surface of said bearing element intermediate each balancing recess and the adjacent inlets andreduction recesses providing outlets from said balancing recesses which are variably restricted in accordance with the spacing between the inner surface of said bearing element and the adjacent surface of the shaft carried thereby.

15. A device comprising a support having a bore defining an inner cylindrical surface, a

member in said bore havin: an outer cylindrical surface laterally movable in said bore, nuid supply control means comprising sets of fluid inlets opening into one of said surfaces and reduction recesses adjacent to said inlets to receive a now 5 of nuld therefrom variably restricted in accordance with the spacing between said surfaces, relatively large balancingv recesses formed in said one surface alternated between and in circumferential alisnment with `said sets of inlets and reduction recesses. passages interconnecting each of said reduction recesses with a diametrically opposite balancing recess, and grooves in said one surface intermediate each balancing recess and the adjacent inlets and reduction recesses providing outlets from said balancing recesses which arer variably restricted in accordance with the spacing between said surfaces.

FRANKW. HOFFER.

REFERENCES yCITED Number Number UNITED STATES PATENTS i Name Date Luxnbv June 29, 1897 Cook May 3, 1898 Capewell Feb. 11, 1902 t Kruesl Mar. 12, 1907 Lasche May 12, 1907 Penick'.. May 2, 1933 Warren July 28, 1936 Thoma Apr. 25, 1939 Dall l- May 30, 1939 Stacy June 25, 1940 FOREIGN PATENTS Country Date Denmark Apr. 18, 1929 Germany Feb. 27, 1908 Y Great Britain Aug. 25, 1932 file of this patent:

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